Urea addition and litter manipulation alter plant community and soil microbial community composition in a Kobresia humilis meadow

Overgrazing and climate change strongly affect alpine meadows by decreasing the plant community biomass and deteriorating the soil environment. To understand how the plant community and soil microbial community structure respond to grazing and N deposition, we conducted an experiment to remove or maintain the plant litter under the chronic addition of N in the Haibei Alpine Meadow in 2005. The experiment included four treatments: added N (þN, 20 g m 2) with the litter removed (LR), þN with the litter left intact (LI), LI without N addition ( N), and LR with N. Soil samples were collected at depths of 0e10 and 10e20 cm, and the following parameters were measured: 1) aboveground biomass (AGB) and litter biomass and 2) microbial community composition and content. Overall, the AGB and litter biomass significantly increased by 45.85% and 50.42% in response to N addition, whereas litter removal increased the AGB by 52.96%. The addition of urea N significantly decreased the PLFA content of the bacterial, gram-positive (Gþ), gram-negative (G ) at a soil of 0e10 cm in the LI and LR treatments by 64.87%, 61.82%, 76.07% and 64.86%, 53.02%, 51.44%, respectively. However, the PLFA content of the bacterial increased from 37.09 to 53.54 nmol g 1 and from 37.09 to 62.05 nmol g 1 at a depth of 10e20 cm for the þN þ LI and þN þ LR treatments compare to the LRþ( )N treatment, respectively. In addition, the total PLFAs in the LRþ( )N treatment significantly increased by 50.61% at a depth of 0e10 cm but decreased from 121.62 to 42.31 nmol g 1 at a depth of 10e20 cm relative to the LIþ( )N treatment. Using PLFA as a biomarker, we detected that G bacteria and total PLFA generally increased with increasing soil depth in the þN plots. However, the content of G was the highest at a depth of 0e10 cm and the lowest at a depth of 10e20 cm in the LR plots. The modification of soil microbial biomass at a depth of 0e10 cm was induced by the bottom-up effect of changes in soil nutrient contents and using ability, which were driven by N addition and litter manipulation. Thus, different soil depths with different soil nutrient conditions resulted in a strong microbial community composition gradient. © 2015 Published by Elsevier Masson SAS.